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Transcript
Zika Virus Outside Africa
Edward B. Hayes
Zika virus (ZIKV) is a flavivirus related to yellow fever,
dengue, West Nile, and Japanese encephalitis viruses. In
2007 ZIKV caused an outbreak of relatively mild disease
characterized by rash, arthralgia, and conjunctivitis on Yap
Island in the southwestern Pacific Ocean. This was the first
time that ZIKV was detected outside of Africa and Asia. The
history, transmission dynamics, virology, and clinical manifestations of ZIKV disease are discussed, along with the
possibility for diagnostic confusion between ZIKV illness
and dengue. The emergence of ZIKV outside of its previously known geographic range should prompt awareness of
the potential for ZIKV to spread to other Pacific islands and
the Americas. I
n April 2007, an outbreak of illness characterized by rash,
arthralgia, and conjunctivitis was reported on Yap Island
in the Federated States of Micronesia. Serum samples from
patients in the acute phase of illness contained RNA of Zika
virus (ZIKV), a flavivirus in the same family as yellow fever, dengue, West Nile, and Japanese encephalitis viruses.
These findings show that ZIKV has spread outside its usual
geographic range (1,2).
Sixty years earlier, on April 18, 1947, fever developed
in a rhesus monkey that had been placed in a cage on a
tree platform in the Zika Forest of Uganda (3). The monkey, Rhesus 766, was a sentinel animal in the Rockefeller
Foundation’s program for research on jungle yellow fever.
Two days later, Rhesus 766, still febrile, was brought to
the Foundation’s laboratory at Entebbe and its serum was
inoculated into mice. After 10 days all mice that were inoculated intracerebrally were sick, and a filterable transmissible agent, later named Zika virus, was isolated from
the mouse brains. In early 1948, ZIKV was also isolated
from Aedes africanus mosquitoes trapped in the same forAuthor affiliation: Barcelona Centre for International Health Research, Barcelona, Spain
DOI: 10.3201/eid1509.090442
est (4). Serologic studies indicated that humans could also
be infected (5). Transmission of ZIKV by artificially fed
Ae. aegypti mosquitoes to mice and a monkey in a laboratory was reported in 1956 (6).
ZIKV was isolated from humans in Nigeria during
studies conducted in 1968 and during 1971–1975; in 1
study, 40% of the persons tested had neutralizing antibody
to ZIKV (7–9). Human isolates were obtained from febrile
children 10 months, 2 years (2 cases), and 3 years of age,
all without other clinical details described, and from a 10
year-old boy with fever, headache, and body pains (7,8).
From 1951 through 1981, serologic evidence of human
ZIKV infection was reported from other African countries such as Uganda, Tanzania, Egypt, Central African
Republic, Sierra Leone (10), and Gabon, and in parts of
Asia including India, Malaysia, the Philippines, Thailand,
Vietnam, and Indonesia (10–14). In additional investigations, the virus was isolated from Ae. aegypti mosquitoes
in Malaysia, a human in Senegal, and mosquitoes in Côte
d’Ivoire (15–17). In 1981 Olson et al. reported 7 people
with serologic evidence of ZIKV illness in Indonesia (11).
A subsequent serologic study indicated that 9/71 (13%)
human volunteers in Lombok, Indonesia, had neutralizing
antibody to ZIKV (18). The outbreak on Yap Island in
2007 shows that ZIKV illness has been detected outside of
Africa and Asia (Figure 1).
Dynamics of Transmission
ZIKV has been isolated from Ae. africanus, Ae. apicoargenteus, Ae. luteocephalus, Ae. aegypti, Ae vitattus,
and Ae. furcifer mosquitoes (9,15,17,19). Ae. hensilii was
the predominant mosquito species present on Yap during
the ZIKV disease outbreak in 2007, but investigators were
unable to detect ZIKV in any mosquitoes on the island during the outbreak (2). Dick noted that Ae. africanus mosquitoes, which were abundant and infected with ZIKV in the
Zika Forest, were not likely to enter monkey cages such as
Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 15, No. 9, September 2009
1347
SYNOPSIS
Figure 1. Approximate known distribution of Zika virus, 1947–
2007. Red circle represents Yap Island. Yellow indicates human
serologic evidence; red indicates virus isolated from humans; green
Figure 1. Approximate
known
distribution of Zika Virus, 1947–2007.
represents
mosquito
isolates.
the one containing Rhesus 766 (5) raising the doubt that
the monkey might have acquired ZIKV from some other
mosquito species or through some other mechanism. During the studies of yellow fever in the Zika Forest, investigators had to begin tethering monkeys in trees because caged
monkeys did not acquire yellow fever virus when the virus
was present in mosquitoes (5). Thus, despite finding ZIKV
in Ae. Africanus mosquitoes, Dick was not sure whether or
not these mosquitoes were actually the vector for enzootic
ZIKV transmission to monkeys.
Boorman and Porterfield subsequently demonstrated
transmission of ZIKV to mice and monkeys by Ae. aegypti
in a laboratory (6). Virus content in the mosquitoes was
high on the day of artificial feeding, dropped to undetectable levels through day 10 after feeding, had increased by
day 15, and remained high from days 20 through 60 (6).
Their study suggests that the extrinsic incubation period for
ZIKV in mosquitoes is ≈10 days. The authors cautioned
that their results did not conclusively demonstrate that Ae.
aegypti mosquitoes could transmit ZIKV at lower levels
of viremia than what might occur among host animals in
natural settings. Nevertheless, their results, along with the
viral isolations from wild mosquitoes and monkeys and the
phylogenetic proximity of ZIKV to other mosquito-borne
flaviviruses, make it reasonable to conclude that ZIKV is
transmitted through mosquito bites.
There is to date no solid evidence of nonprimate reservoirs of ZIKV, but 1 study did find antibody to ZIKV in
rodents (20). Further laboratory, field, and epidemiologic
studies would be useful to better define vector competence
for ZIKV, to determine if there are any other arthropod
vectors or reservoir hosts, and to evaluate the possibility of congenital infection or transmission through blood
transfusion.
1348
Virology and Pathogenesis
ZIKV is an RNA virus containing 10,794 nucleotides
encoding 3,419 amino acids. It is closely related to Spondweni virus; the 2 viruses are the only members of their clade
within the mosquito-borne cluster of flaviviruses (Figure 2)
(1,21,22). The next nearest relatives include Ilheus, Rocio,
and St. Louis encephalitis viruses; yellow fever virus is the
prototype of the family, which also includes dengue, Japanese encephalitis, and West Nile viruses (1,21). Studies in
the Zika Forest suggested that ZIKV infection blunted the
viremia caused by yellow fever virus in monkeys but did
not block transmission of yellow fever virus (19,23).
Information regarding pathogenesis of ZIKV is scarce
but mosquito-borne flaviviruses are thought to replicate
initially in dendritic cells near the site of inoculation then
spread to lymph nodes and the bloodstream (24). Although
flaviviral replication is thought to occur in cellular cytoplasm, 1 study suggested that ZIKV antigens could be
found in infected cell nuclei (25). To date, infectious ZIKV
has been detected in human blood as early as the day of
illness onset; viral nucleic acid has been detected as late as
11 days after onset (1,26). The virus was isolated from the
serum of a monkey 9 days after experimental inoculation
(5). ZIKV is killed by potassium permanganate, ether, and
temperatures >60°C, but it is not effectively neutralized
with 10% ethanol (5).
Clinical Manifestations
The first well-documented report of human ZIKV disease was in 1964 when Simpson described his own occupationally acquired ZIKV illness at age 28 (27). It began
with mild headache. The next day, a maculopapular rash
covered his face, neck, trunk, and upper arms, and spread
to his palms and soles. Transient fever, malaise, and back
pain developed. By the evening of the second day of illness
he was afebrile, the rash was fading, and he felt better. By
day three, he felt well and had only the rash, which disappeared over the next 2 days. ZIKV was isolated from serum
collected while he was febrile.
In 1973, Filipe et al. reported laboratory-acquired
ZIKV illness in a man with acute onset of fever, headache,
and joint pain but no rash (26). ZIKV was isolated from
serum collected on the first day of symptoms; the man’s
illness resolved in ≈1 week.
Of the 7 ZIKV case-patients in Indonesia described
by Olson et al. all had fever, but they were detected by
hospital-based surveillance for febrile illness (11). Other
manifestations included anorexia, diarrhea, constipation,
abdominal pain, and dizziness. One patient had conjunctivitis but none had rash. The outbreak on Yap Island was
characterized by rash, conjunctivitis, and arthralgia (1,2).
Other less frequent manifestations included myalgia, headache, retroorbital pain, edema, and vomiting (2).
Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 15, No. 9, September 2009
Zika Virus Outside Africa
among those with apparent primary ZIKV infections (1,2).
Cross-reactivity was more frequently noted with dengue virus than with yellow fever, Japanese encephalitis, Murray
Valley encephalitis, or West Nile viruses, but there were
too few samples tested to derive robust estimates of the
sensitivity and specificity of the ELISA. IgM was detectable as early as 3 days after onset of illness in some persons; 1 person with evidence of previous flavivirus infection had not developed IgM at day 5 but did have it by day
8 (1). Neutralizing antibody developed as early as 5 days
after illness onset. The plaque reduction neutralization assay generally has improved specificity over immunoassays,
but may still yield cross-reactive results in secondary flavivirus infections. PCR tests can be conducted on samples
obtained less than 10 days after illness onset; 1 patient from
Yap Island still had detectable viral RNA on day 11 (1). In
general, diagnostic testing for flavivirus infections should
include an acute-phase serum sample collected as early as
possible after onset of illness and a second sample collected
2 to 3 weeks after the first.
Figure 2. Phylogenetic relationship of Zika virus to other flaviviruses
based on nucleic acid sequence of nonstructural viral protein 5,
with permission from Dr Robert Lanciotti (1). Enc, encephalitis; ME,
meningoencephalitis.
Diagnosis
Diagnostic tests for ZIKV infection include PCR tests
on acute-phase serum samples, which detect viral RNA,
and other tests to detect specific antibody against ZIKV in
serum. An ELISA has been developed at the Arboviral Diagnostic and Reference Laboratory of the Centers for Disease Control and Prevention (Atlanta, GA, USA) to detect
immunoglobulin (Ig) M to ZIKV (1). In the samples from
Yap Island, cross-reactive results in sera from convalescent-phase patients occurred more frequently among patients with evidence of previous flavivirus infections than
Public Health Implications
Because the virus has spread outside Africa and Asia,
ZIKV should be considered an emerging pathogen. Fortunately, ZIKV illness to date has been mild and self-limited,
but before West Nile virus caused large outbreaks of neuroinvasive disease in Romania and in North America, it was
also considered to be a relatively innocuous pathogen (28).
The discovery of ZIKV on the physically isolated community of Yap Island is testimony to the potential for travel
or commerce to spread the virus across large distances. A
medical volunteer who was on Yap Island during the ZIKV
disease outbreak became ill and was likely viremic with
ZIKV after her return to the United States (2). The competence of mosquitoes in the Americas for ZIKV is not
known and this question should be addressed. Spread of
ZIKV across the Pacific could be difficult to detect because
of the cross-reactivity of diagnostic flavivirus antibody assays. ZIKV disease could easily be confused with dengue
and might contribute to illness during dengue outbreaks.
Recognition of the spread of ZIKV and of the impact of
ZIKV on human health will require collaboration between
clinicians, public health officials, and high-quality reference laboratories.
Given that the epidemiology of ZIKV transmission on
Yap Island appeared to be similar to that of dengue, strategies for prevention and control of ZIKV disease should
include promoting the use of insect repellent and interventions to reduce the abundance of potential mosquito vectors. Officials responsible for public health surveillance in
the Pacific region and the United States should be alert to
the potential spread of ZIKV and keep in mind the possible
diagnostic confusion between ZIKV illness and dengue.
Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 15, No. 9, September 2009
1349
SYNOPSIS
Acknowledgment
The author thanks Marc Fischer for helpful comments on the
manuscript.
Dr Hayes is currently a research professor at the Barcelona
Centre for International Health Research. His research interests
include epidemiology and prevention of vector-borne infectious
diseases, and evaluation of safety and effectiveness of preventive
interventions.
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Address for correspondence: Edward B. Hayes, Barcelona Centre for
International Health Research, Rosello 132, Barcelona 08037, Spain;
email: [email protected]
Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 15, No. 9, September 2009